Device for the controlled delivery of liquids and/or creamy substances and/or flowable substances

ABSTRACT

The invention concerns a device ( 4 ) for the controlled delivery of a product (P), such as liquids and/or creamy substances and/or flowable substances within a container ( 1 ), in such a way that in the delivery position the product (P) column to be delivered is in a raised position with respect to said device ( 4 ), said container ( 1 ) being comprised of a material, said material being deformable by squeezing and able to energetically returning to its original shape, once the squeezing action is interrupted, and being provided with a neck ( 15 ), being further eventually provided a cap element ( 2 ), coupled with said neck ( 15 ), and provided with an outlet opening ( 3 ) for the product to be delivered toward said device ( 4 ), said controlled delivery device ( 4 ) being characterised in that it comprises means for the controlled delivery of the product, said means for the controlled delivery comprising a first inner conduct ( 5 ), communicating ( 3 ) inside the container, a second inversion conduct ( 7 ), communicating ( 6 ) with said first inner conduct ( 5 ), and within which the run of the product (P) is directed according to a direction substantially opposed to the gravity force during the delivery phase, without passage of outer air toward the inside of the container ( 1 ), and a third outer conduct ( 9 ), communicating ( 8 ) with said inversion conduct ( 7 ) and provided with product (P) delivery opening ( 10 ); the inlet opening ( 6 ) of the inversion conduct ( 7 ) being realised in such a way to prevent the entrance of air within the container ( 1 ), when the product (P) during its exit from inside the container ( 1 ) has reached the inversion conduct ( 7 ).

[0001] The present invention relates to a device for the controlled delivery of liquids and/or creamy substances and/or flowable substances, allowing to control the outlet of the substance contained within the container, automatically interrupting the outlet after the squeezing action on the same container.

[0002] Containers are known, provided with elastic systems allowing to open and close an opening, and mainly comprised of plastic material, in order to try to obtain a controlled delivery.

[0003] Solutions available on the market that are complicated and expensive are not able to realise a device that can be manufactured with reduced costs.

[0004] Differently to the known solutions, the solution suggested according to the present invention, does not provide elastic systems, since the substance to be delivered is not stopped by the closure systems, but it is interrupted by the dynamic action of the atmospheric pressure, not providing closure walls between the delivery opening and the inside the container.

[0005] The solution suggested according to the present invention can be realised with very low costs, and it is substantially suitable to deliver any kind of liquid or fluid product, such as low density liquids, as water and beverages; medium density liquids, such as high density liquid soaps, sauces, fluids, for example low density creamy substances.

[0006] It is therefore specific object of the present invention a device for the controlled delivery of a product, such as liquids and/or creamy substances and/or flowable substances within a container, in such a way that in the delivery position the product column to be delivered is in a raised position with respect to said device, said container being comprised of a material, said material being deformable by squeezing and able to energetically returning to its original shape, once the squeezing action is interrupted, and being provided with a neck, being further provided a cap element, coupled with said neck, and provided with an outlet opening for the product to be delivered toward said device, said controlled delivery device being characterised in that it comprises means for the controlled delivery of the product, said means for the controlled delivery comprising a first inner conduct, communicating inside the container, a second inversion conduct, communicating with said first inner conduct, and within which the run of the product is directed according to a direction substantially opposed to the gravity force during the delivery phase, without passage of outer air toward the inside of the container, and a third outer conduct, communicating with said inversion conduct and provided with product delivery opening; the inlet opening of the inversion conduct being realised in such a way to prevent the entrance of air within the conduct, when the product during its exit from inside the container has reached the inversion conduct.

[0007] Preferred embodiments of the device according to the invention are described in the dependent claims.

[0008] The present invention will be now described, for illustrative but not limitative purposes, according to its preferred embodiments, with particular reference to the figures of the enclosed drawings, wherein:

[0009]FIG. 1 and FIG. 2 respectively show a tube shaped container and a bottle shaped container, both closed by a closure cap provided with a product control device with a S-shaped conduct;

[0010]FIGS. 1a and 2 a are top views only of caps of the FIGS. 1 and 2;

[0011]FIGS. 3 and 4 show containers of FIG. 2 respectively rotated of 90° and 180°;

[0012]FIGS. 5, 6, 7 and 8 show some modifications of the container of FIG. 4;

[0013]FIG. 7a shows section VII-VII of embodiment of FIG. 7;

[0014]FIGS. 9 and 10 show the final end of a container provided with a cap having a product control device and a laterally hinged cover, suitable for sauces;

[0015]FIG. 11 shows the cap provided with product control device and cover disassembled and realised as a single pressed piece, provided with two lateral hinges for assembling;

[0016]FIGS. 12, 13, 14 show modifications of FIGS. 9, 10, 11, suitable for low density and low capillarity liquids;

[0017]FIG. 15 shows a modification of FIG. 14 with a lateral delivery, more suitable for liquids subjected to capillarity;

[0018]FIG. 16 shows a container provided with a cap with product control device provided within the container;

[0019]FIG. 17 and FIG. 18, with a view rotated of 90°, show a modification of FIG. 16, having an opening and closure system of the product delivery by 90° rotation;

[0020]FIGS. 17a and 18 a respectively show sections XVII-XVII and XVIII.XVIII of FIGS. 17 and 18;

[0021]FIGS. 19, 19a, 20, 21, 22 show the modifications of the final ends of containers of FIGS. 16, 17, 18, where FIGS. 20 and 22 show modifications provided with opening and closure system of the product delivery, the first one with a pushing and pulling axial system, the second one by roto-translation.

[0022] In the various views, the corresponding parts will be indicated by the same references.

[0023] Referring to FIG. 1, it is shown a tube shaped container, having a base realised by welding of its final end, filled in with product P to level 11, in a not-delivery position, having a cap 2 closing by threading on its threaded neck 15.

[0024] In FIG. 2, it is shown a bottle shaped container 1 in a vertical position, resting on its base, filled in with the product P up to the level 11, having a cap 2 closing by threading on its threaded neck 15.

[0025] Both containers of FIG. 1, tube 1′ , and of FIG. 2, bottle 1, provide the cap 2 with an opening 3 allowing to the product P to pass within the delivery control device, generically indicated by the reference number 4, realised by a S-shaped conduct, before being delivered through the delivery opening 10, following the squeezing of the tube 1′ or of the bottle 1.

[0026] Both containers must be comprised of tough and elastic material in such a way to have the force of returning after their squeezing to the original shape.

[0027] S-shaped conduct, determining the product P delivery control device 4, is comprised of the following three parts placed according to the following sequence:

[0028] a first inner conduct 5, having its inlet end at the opening 3 of the cap 2, communicating with inside of the containers, or 1′ axially outwardly directed;

[0029] a second conduct, or inversion conduct 7, within which the path of the product P is directed according to a direction substantially opposed to the gravity force in the delivery position, having a first end, or inlet end 6, communicating with said opening of the second end of the first inner conduct, and a second end provided with an opening, of outlet opening 8;

[0030] a third outer conduct 9 having a first end communicating with said outlet opening 8 of the second end of the inversion conduct and a second end provided with product P delivery opening 10.

[0031] In FIG. 1a and FIG. 2a top views of the cap 2 are shown, without tube 1′ or bottle 1, provided with the S-shaped control device 4 having a circular delivery opening 10.

[0032] In the figures, length of the conducts is shown interrupted, since it will be chosen in function of the specific use.

[0033] In the following figures, caps 2 are shown, provided with product P control device 4, closed on the bottle shaped containers 1, taking into account that they can be also used tube shaped containers 1′.

[0034] In FIG. 3 it is illustrated container 1 of FIG. 2, rotated of 90°, having the delivery opening 10 in an outwardly directed horizontal position.

[0035] When container 1, having the delivery opening 10 directed upward and the upper level of the product communicating with the outer, starts rotating from its vertical position of FIG. 2 to the horizontal position of FIG. 3, product P moves to reach the opening 3 of the cap to pass within the inner conduct 5.

[0036] As soon as the product P has reached the inlet opening 6, between the inner conduct 5 and the inversion conduct 7, outer air can no more enter within the container.

[0037] When the container 1 is rotated of 90°, air remained inside sale upwards, to reach the upper side of the container 1, determining a corresponding level 12 of the product P in a not-delivery position.

[0038] Being the inner level in a position raised with respect to the inlet opening 6, between inner conduct 5 and inversion conduct 7, it tends to exit passing through the inversion conduct.

[0039] There is no air entering corresponding to the product P tending to exit.

[0040] Level 12 of inner product P tends to lower to the position indicated in FIG. 3, and air remained within the container 1 tends to increase its volume and correspondingly to diminish the pressure, with respect to the initial position when the product P reached the inlet opening 6.

[0041] Product P, tending to exit through the inversion conduct 7, while its level sale within the inversion conduct 7, is at the same time returned inside, since on the outer conduct 9 a higher outer pressure with respect to the air pressure remained within the container 1 is present, said inner pressure decrescendo while the product P exits and sale within the inversion conduct 7.

[0042] Equilibrium of product P within the inversion conduct 7 is reached when the depression of the air remained within the container is able to call back by sucking the weight of the product P column raised with respect to the inlet opening 6.

[0043] If the outlet opening 8, between the inversion conduct 7 and the outer conduct 9, is raised with respect to the dynamic equilibrium level 13 reached in the inversion conduct 7, the product P does not exit from the delivery opening 10 provided on the end of the outer conduct 9.

[0044] In this situation, the exit of the product P stops at the dynamic equilibrium level 13 within the inversion conduct 7, thus preventing the dropping through the delivery opening 10.

[0045] If the body of the container 1 is subjected to a squeezing action, shrinks its inner volume, thus modifying the equilibrium, and the product P is compressed and forced to exit within the conducts of the delivery control device 4 through the delivery opening 10.

[0046] If the container 1 is comprised of tough and elastic material, once interrupted the squeezing action of the container 1 m the latter, in view of the material by which it is made up, comes back to the original shape sucking both the product P remained within the conducts 5, 7, 9 and once the product 2 within the conducts 5, 7, 9 is back within the container 1, outer air enters again, compensating the amount of product P exited.

[0047] In conclusion, when the container is again in its original shape, the above situation is restored, with the dynamic equilibrium level reaching a lower level with respect to the outlet opening 8, thus preventing dropping of the product.

[0048] By the delivery control device 4 suggested according to the present invention, product P can only exit following to a squeezing action of the container 1. Once interrupted the squeezing phase of the container 1, product P automatically stops, due to the outer atmospheric pressure dynamically controlling the equilibrium level 13 within the inversion conduct 7.

[0049] Dynamic equilibrium level 13 can vary also as a consequence of outer temperature variations of the container 1, since air remained inside can vary in volume due to the temperature variation and said volume variation can exert a further pressure on the product level that, pushed to exit, would modify the dynamic equilibrium level reached within the inversion conduct 7. This effect is more sensitive in function of the higher quantity of air remained within the container 1. When the container is rotated of 180° with respect to the position shown in FIG. 2, or of 90° with respect to the position of FIG. 3, takes the position of FIG. 4 where the container is in a upset position, with the delivery opening 10 downward directed.

[0050] Also in this case, if the dynamic equilibrium level 13 is realised within the inversion conduct 7, product P not passing the outlet opening 8, it does not exit, but after the squeezing of the container 1, even in presence of a product P column at a higher level with respect to the delivery opening 10.

[0051] In FIG. 5 it is shown a different embodiment of the container 1 of FIG. 3, with the container axis placed at 90° with respect to its neck in such a way to have a lateral delivery from a vertical container.

[0052] In FIG. 6, it is shown a different embodiment of the container 1 of FIG. 4, wherein the outer conduct 9 is realised at 90° with respect to the inversion conduct 7 in such a way to have a lateral delivery with the container 1 upside-down.

[0053] In FIG. 7 is shown a different embodiment of the delivery control device 4 of FIG. 4, wherein conducts 5, 7, 9, have different shape with respect to those of the previous embodiments, even if the product P runs also in this case a S shaped path before exiting from the delivery opening 10.

[0054] In this case, conducts 5, 7, 9 are realised with different diameters, wherein the outer conduct 9 is placed inside the inversion conduct 7, and both of them are placed inside the inner conduct 5, laterally displaced to have all of them adjacent lateral walls. Section along axis VII-VII of said configuration of the conducts 5, 7, 9 is shown in FIG. 7a.

[0055] In FIG. 8 a different embodiment of the delivery control device 4 of FIG. 4 and of FIG. 7 is shown, wherein conducts 5, 7, 9 have a different shape with respect to the previous solutions, even if the product P, before exiting, runs a S shaped path.

[0056] Inner 5 and outer 9 conducts are both placed within the inversion conduct 7, that is realised with a very larger diameter, and are placed in a position opposite each other within the inversion conduct 7.

[0057] In the present embodiment, it is necessary a higher product volume P to carry out a corresponding variation of the dynamic equilibrium level 13 within the inversion conduct 7.

[0058] This solution, with respect to the preceding ones, is less sensitive to the variations of the dynamic equilibrium level due to the temperature variations acting by volume and pressure variations on the air remained within the container 1, variations acting on the surface of the inner product, thrusting the same to exit or to return in function of the fact that the temperature is higher or lower with respect to the equilibrium conditions reached during the last product P exit.

[0059] In the following figures, from FIG. 9 to FIG. 14, some applications are shown of the embodiments previously illustrated, with the container 1 represented as a partial view of its final part provided with the neck, with the delivery opening upward directed, in a resting position, and the delivery opening downward directed in a upset position.

[0060] In FIGS. 9, 10 and 11 it is shown the final end of a container 1, having a very reduced height of the delivery control device 4, suitable to very dense liquids like sauces, more specifically tomato sauce.

[0061] A cover 16, provided with a lateral hinge 17 on its upper end of the inversion conduct engages by a snapping closure 18 on the final end of the delivery opening 10, as indicated in FIG. 10. This solution is also used for the containers described in the following FIGS. 12, 13, 14.

[0062] Inner conduit 5 and outer conduit 9 are placed on two different bodies, engaged by pressure, snapping, or ultrasound welding, to realise a recipient 7 corresponding to the inversion conduct.

[0063] Inner conduct 5 is moved toward the right side, the inner wall of which is adjacent and corresponding to the inner wall of the neck 15 of the container 1, while the outer conduct 9 is positioned slightly on the left and is realised, with respect to the previous embodiments, shorter in its inner part of the inversion conduct 7, in order to have the end faced toward the cap 2, creating the exit opening 8, enough far from the latter.

[0064] After the delivery, when the container 1 goes back to its not delivery position, FIG. 10, with the base of the container at the bottom and delivery opening 10 upward, the product remained within the inversion conduct 7 and in the inlet opening 6, as illustrated in FIG. 9, inverts, thus occupying the new upset position in the opposed surface of said inversion conduit, as illustrated in FIG. 10.

[0065] It is suitable that level 14 of the product in the not-delivery position within the inversion conduct 7, see FIG. 10, is lower than the end toward the cap 2 of the outer conduct 9, determining the outlet opening 8 of the inversion conduct 7, so that the inner air remained within the contained 1, if subjected to positive volume and pressure variation due to positive temperature variation, can exit passing through the product level 14 and the inner end of said outer conduct 9, determining said exit opening 8 of the inversion conduct 7.

[0066] To prevent dropping of the product, the inner end of the outer conduct 9, that is inside the inversion conduct 7, see FIG. 9, must be in any case at a level higher than the end opposite to the inner conduct 5, determining the inlet opening 6 of the inversion conduct 7, to ensure that outer air cannot enter within the container 1 in a upset position.

[0067] A covering wall 19, realised by the bottom wall of the cap s, slightly distant from the inner end of the outer conduct 9, corresponding to the outlet exit 8, allows to prevent that some product P remained entrapped within the inversion conduct 7, above said outer conduct 9, can exit in a not checked way, through said outer conduct 9 from the delivery opening.

[0068] This solution is also used in the containers shown in the following FIGS. 12, 13, 14, 19, 20, 21 and 22.

[0069] Cap 2, control device 4 and cover 16 of FIGS. 9 and 10 can be realised, as illustrated in FIG. 11, as a single pressed body, comprised of three bodies coupled each other by lateral hinges 17, 20, then closed and assembled.

[0070] In the solution shown in FIG. 12, suitable for low density liquids, the inversion conduct 7 has a higher height to allow that the dynamic equilibrium level 13 has the possibility of reaching a higher height and a bigger excursion in case of temperature variations.

[0071] The inversion conduct 7 has a lower portion wherein the tubular wall surrounds the end of the inner conduct 5, while the upper portion has an outer wall corresponding to the outer wall of the cap 2.

[0072] This solution has the advantage of limiting the amount of product P necessary to reach the dynamic equilibrium level 13, and therefore to limit the amount of product remained within the inversion conduct 7 when the container is upset.

[0073] In the solution shown in FIG. 13, suitable for medium density liquids having a certain degree of capillarity, such as soaps, the inversion conduct 7 has a lower wall 21 provided with an upwardly directed recess, to allow to the outer conduct 9 to be very short, even if the inner end, corresponding to the outlet opening 8 of the inversion conduct 7, is positioned at a medium height of said inversion conduct.

[0074] After the delivery, even if product P is sucked, an amount corresponding to a thin film remains adhering by capillarity and after few seconds, due to the gravity, tends to descend and to create a residual dropping of one or two droplets.

[0075] In this embodiment, this effect is substantially eliminated, being the conduct really short to limit at the maximum the amount of product P that can be deposited by capillarity.

[0076] In the embodiment of FIG. 14, inversion conduct 7 has a sloping wall 22, to obtain the advantages of the embodiment of FIG. 12, i.e. a wall surrounding the final end of the inner conduct 5, and those of FIG. 13, i.e. the outer conduct 9 very short.

[0077] In FIGS. 12, 13, 14, cap 2, control device 4 and cover 16 of FIG. 9 and 10 can be made up as a single pressed body, as shown in FIG. 11, comprising three bodies, coupled each other by lateral hinges 17, 20, then closed and assembled.

[0078] In FIG. 15, it is shown a modification of FIG. 14 more suitable for medium density liquids having a certain capillarity degree, such as soaps, since the container 1 is realised to stably remain in a upset position, and the outer conduct 9 is realised with a 90° angle with respect to the inversion conduct 7, to have a lateral exit of the product P.

[0079] Being the outer conduct 9 horizontal, and even better if it is slightly sloped upward, after the delivery of product P, remained adhering by capillarity, tends to descend within the inversion conduct 7, under the gravity force, preventing the residual dropping from the delivery opening 10.

[0080] In the following figures, from FIG. 16 to FIG. 20, containers 1 are shown, having the control device 4 for the product P delivery provided inside the container, with the outer conduct placed on the cap 2 or on a movable bottom coupled to the same.

[0081] In FIG. 16, in the simplest solution, the inversion conduct 7 and the outer conduct 9 are realised with the same section within the inner conduct 5 comprised of the inner wall of the neck 15 of the container 1.

[0082] In FIGS. 17, 17a, 18, 18 a it is shown a container having a rotation closure and opening system of the cap 2, snapping coupled on the container 1, able to open or to close the inner end of the outer conduct 9.

[0083] A tubular receptacle 23, provided with a bottom 24, having on the opposite end an annular flange 25 faced outwardly, engaging on the edge of the container 1 neck, realises, along with the bottom of the rotating cap 2, the inversion conduct 7.

[0084] Two opposite tubular C shaped recesses are realised on the outer tubular wall of the inversion conduct 7, see FIGS. 17a, 18 a, one 26 of which making part of the inlet conduct 5 along with the remaining part of the corresponding inner surface of the container 1 neck.

[0085] On the bottom of said tubular recess 26, close to the cap 2, it is realised an inlet opening 6 allowing the entrance of the product P within the inversion conduct 7.

[0086] On the opposite side, following to the rotation of the cap 2, the outer conduct 9 rotates within the inversion conduct, while its inner end, realising the outlet opening 8, is closed by a closure bottom wall 27 obtained by the opposed tubular C shaped recess 28.

[0087] Rotating the cap 2, the outer conduct 9 rotates of 90° with respect to the container 1 and to the receptacle 7 realising the inversion conduct, FIGS. 18, 18a, and the inner end of the outer conduct 9 rotates with respect to the closure bottom wall 27 realised on the bottom of the opposed tubular C shaped recess 28, thus allowing to the product P to exit from the delivery opening 10 of the outer conduct 9.

[0088] This solution allows to have one body less, corresponding to the closure cover 16, and a better use practicality.

[0089] In FIG. 19, it is shown a container 1 having the product P control device inside, with the outer conduct on the cap 2.

[0090] As in FIG. 10, said container 1 is provided with a cover 16 engaged by a lateral hinge with the cap 2, with an inner end of the outer body 9, corresponding to the outlet opening 8, substantially placed at half height of the inversion conduct 7 and slightly distant from a cover wall 19 obtained from the bottom wall of the cap 2, and with an inversion conduct 7, having a diameter slightly more little than the inner wall of the container 1 neck 15.

[0091] A receptacle 29, having closed bottom and opposite end free, realising along with the bottom of the cap 2 the inversion conduct 7, is pressure coupled, or ultrasound glued, with the edges of the cross vertical walls 31 projecting from the inner portion of the outer body 9, see FIG. 19a.

[0092] On the edge 32 of the receptacle 29, contacting the bottom of the cap 2, it is realised the inlet opening 6, to allow to the product to enter within the inversion conduct 7.

[0093] In FIG. 20, it is shown a container 1 having an axial opening and closing system of the push and pull kind, for the inner end of the outer body.

[0094] A cap 2 threaded on the neck 15 of the container 1 is provided with a bottom re-entrant within the container, thus determining a first inner receptacle 33, provided with tubular wall adjacent to the inner tubular wall of the container 1 neck 15, and with a bottom surface 34, the latter making part of the inversion conduct 7.

[0095] A second slidable tubular receptacle 35, with a bottom provided with outer conduct 9, tubular wall, realising the remaining part of the inversion conduct 7, and opposite end opened, is slidably, sealing, telescopically inserted, in a upset position, within the tubular wall of the first inner receptacle 33 obtained from the cap 2 recess.

[0096] Axial engagement means are realised by an annular projection 36, comprising a little edge on the second slidable tubular receptacle 35, sliding within an annular groove 37 obtained on the final end of the inner wall of the first inner receptacle 33, realised from the cap 2 recess.

[0097] Inner conduct 5, having the base on the bottom of the first inner receptacle 33 and opposed end slightly far from the bottom of the second slidable tubular receptacle 35, allows to the product to enter through the inlet opening 6 into the inversion conduct 7.

[0098] In the delivery position, the inner end of the outer conduct 9, corresponding to the outlet opening 8, is slightly far from the covering wall 19 obtained from the bottom wall of the first inner receptacle 33.

[0099] Instead, in the closure position, the second slidable tubular receptacle 35, bringing the outer conduct 9, is pushed within the first inner recipient 33, in such a way that the inner end of the outer conduct 9 can close on the covering wall 19 realised from the bottom wall of said inner receptacle 33 and consequently closing said outlet opening 8 by closing the conduct 9.

[0100] In this situation, product P is prevented from exiting, determining, as in FIG. 17, an arrangement with a reduced number of bodies, namely the closure cover 16, and a better use practicality.

[0101] In FIGS. 21 and 22, containers are shown, having the product P control device within the container 1, suitable for liquids having capillarity.

[0102] In FIG. 21, it is shown a container 1, as in FIG. 20, having a cap 2 threaded on the neck 15 of the container 1 and provided with a bottom re-entrant within the container thus determining a first inner receptacle 38, said receptacle being obtained from the recess of the cap 2, provided with tubular wall adjacent to the inner tubular wall of the container 1 neck 15, and with a bottom surface 39, the latter making part of the inversion conduct 7.

[0103] As in FIG. 17, on the outer tubular wall of said first inner receptacle 38, it is realised a C shaped tubular recess 26, making part of the inlet conduct 5, along with the remaining part of the corresponding inner surface of the container 1 neck.

[0104] On the bottom of said tubular recess, close to the cap 2, it is realised an inlet opening 6 allowing the entrance of the product P within the inversion conduct 7.

[0105] A cover 16, having a lateral hinge 17 on the upper end of the inversion conduct, engages, by a snapping closure, on the final end of the delivery opening 10.

[0106] As in FIG. 13, a second element, provided with a lateral hinge 20 on the upper end of the cap 2, is assembled by a snapping system, or ultrawave welded, to realise the surface of the lower part of the inversion conduct 7 with an upwardly directed recess 21, to allow to the outer conduct 9 to be extremely short, even being the inner end placed at the medium height of the inversion conduct 9.

[0107] As indicated in FIGS. 10, 12, 13, 14, a cover 16, provided with a lateral hinge 17 on the upper end of the control device 4, engages by a snapping closure on the delivery opening 10, while the inner end of the outer body 9 is substantially placed at a half height of the inversion conduct 7, and slightly far from a covering wall 19 obtained from the bottom wall of the inversion conduct 7, corresponding to the first inner receptacle 38.

[0108] In FIG. 22, it is shown a container 1, having a structure similar to the one of FIG. 21, provided with a closure and opening system for the outlet opening 8 by screw rotation of a closure and opening movable body 40 placed above the cap 2 snapping engaged on the container 1 neck 15, said screw rotation of the closure and opening movable body 40 able to open or to close the inner end of the outer conduct 9.

[0109] The closure and opening movable body 40 in its central part realises the lower part of the inversion conduct 7, said central part being provided with an upwardly directed recess 21, to allow to the outer conduct 9 to be extremely short, even being the inner end placed at half height of the inversion conduct.

[0110] In the delivery position, the inner end of the outer conduct 9, as in FIG. 20, is slightly far from the covering wall 19 obtained from the bottom wall 39 of the first inner receptacle 38, obtained from the recess of the cap 2.

[0111] In the closure position, by screwing of the closure and opening movable body 40, bearing the outer conduct 9, is pushed within the first inner receptacle 38, in such a way that the inner end of the outer conduct 9 can close on the covering wall 19 obtained from the bottom wall 39 of the inversion conduct 7, corresponding to the first inner receptacle 38.

[0112] An annular wall 41 projecting from the bottom surface of the closure and opening body 40, realising the lower part of the inversion conduct 7, guarantees a hermetical sealing by a pressure slidable coupling with the inner tubular wall of the first inner receptacle 38 obtained from the recess of the cap 2.

[0113] The present invention has been described for illustrative but not limitative purposes, according to its preferred embodiments, but it is to be understood that modifications and/or changes can be introduced by those skilled in the art without departing from the relevant scope as defined in the enclosed claims. 

1. Device (4) for the controlled delivery of a product (P), such as liquids and/or creamy substances and/or flowable substances within a container (1), in such a way that in the delivery position the product (P) column to be delivered is in a raised position with respect to said device (4), said container (1) being comprised of a material, said material being deformable by squeezing and able to energetically returning to its original shape, once the squeezing action is interrupted, and being provided with a neck (15), being further eventually provided a cap element (2), coupled with said neck (15), and provided with an outlet opening (3) for the product to be delivered toward said device (4), said controlled delivery device (4) being characterised in that it comprises means for the controlled delivery of the product, said means for the controlled delivery comprising a first inner conduct (5), communicating (3) inside the container, a second inversion conduct (7), communicating (6) with said first inner conduct (5), and within which the run of the product (P) is directed according to a direction substantially opposed to the gravity force during the delivery phase, without passage of outer air toward the inside of the container (1), and a third outer conduct (9), communicating (8) with said inversion conduct (7) and provided with product (P) delivery opening (10); the inlet opening (6) of the inversion conduct (7) being realised in such a way to prevent the entrance of air within the container (1), when the product (P) during its exit from inside the container (1) has reached the inversion conduct (7).
 2. Device (4) for the controlled delivery of a product (P) according to claim 1, characterised in that said inversion conduct (7) is able to make the product (P) outflowing in a direction opposite to the gravity force, without passage of outer air toward inside the container (1), thus allowing, during the lowering of the level (12) within the container, a corresponding inner entrapped air volume and depression increase, able to return by sucking the weight of the product (P) column raised with respect to the inlet opening (6) thus allowing to the product (P) to reach a dynamic equilibrium level (13) within said inversion conduct (7), with a dynamic equilibrium between its inlet (6) and outlet (8) openings able to prevent the dropping due to exit of the product (P) through the delivery opening (10).
 3. Device (4) for the controlled delivery of a product (P) according to one of the preceding claims, characterised in that said container (1) is comprised of a material sufficiently tough and elastic suitable to determine the outlet control action of the product (P) by squeezing of the container (1) placed in such a way to have the product (P) column to be delivered in a raised position with respect to the control device (4), particularly with respect to the inlet opening (6), so that following to the squeezing action, the volume of the product (P) contracts within the container (1) to compress and to force said product (P) to exit, making its dynamic equilibrium level (13) rising within the inversion conduct (7), up to pass the outlet opening (8) to exit through the delivery opening (10).
 4. Device (4) for the controlled delivery of a product (P) according to one of the preceding claims, characterised in that said container (1) is comprised of a material sufficiently tough and elastic to have memory to energetically return to its original shape once interrupted the deformation action, suitable to determine a sucking both of the product (P) remained within the conducts (5, 7, 9) of the device for the controlled delivery (4), to prevent residual dropping, and of the air once the product (P) from the conducts (5, 7, 9) is returned within the container (1), in order to compensate the amount of product (P) exited and to restore the initial situation wherein the dynamic equilibrium level (13) of the product (P) within the inversion conduct (7) is in a lower position with respect to the product (P) column to be delivered and automatically stops, stopped by the outer atmospheric pressure dynamically controlling the same.
 5. Device (4) for the controlled delivery of a product (P) according to one of the preceding claims, characterised in that said container (1) is a bottle, a tube, or any other shape.
 6. Device (4) for the controlled delivery of a product (P) according to one of the preceding claims, characterised in that said outer conduct (9) is oriented substantially parallel or perpendicular to the inversion conduct (7).
 7. Device (4) for the controlled delivery of a product (P) according to one of the preceding claims, characterised in that said inner (5), inversion (7) and outer (9) conduct are placed side by side to independent conducts (5, 7, 9); or the inner conduct (5) placed side by side to the inversion conduct (7), the latter containing the outer conduct (9); or the outer conduct (9) placed side by side to the inversion conduct (7), the latter containing the inner conduct (5).
 8. Device (4) for the controlled delivery of a product (P) according to one of the preceding claims 1-6, characterised in that said inner (5), inversion (7) and outer (9) conduct are realised one within the other one, and particularly the inner conduct (5) contains the inversion conduct (7), the latter containing the outer conduct (9); or the inner conduct (5) contains both the inversion conduct (7) and the outer conduct (9); or the inversion conduct (7) contains both the inner conduct (5) and the outer conduct (9).
 9. Device (4) for the controlled delivery of a product (P) according to one of the preceding claims, characterised in that said cap element (2) is fixedly or removably, or by screwing, or movable by rotation, coupled, to the container (1) neck (15).
 10. Device (4) for the controlled delivery of a product (P) according to one of the preceding claims, characterised in that said device (4), along with the cap element (2) and the container (1) neck (15) is substantially positioned at 90° with respect to the container axis (1) containing the same, to realise a lateral delivery.
 11. Device (4) for the controlled delivery of a product (P) according to one of the preceding claims, characterised in that said inner conduct (5) and outer conduct (9) are placed on two different elements with the edges of the relevant walls engaged each other by pressure, or by snapping coupling, or by ultrasound welding, able to realise the receptacle corresponding to the inversion conduct (7).
 12. Device (4) for the controlled delivery of a product (P) according to one of the preceding claims, characterised in that said a second receptacle shaped element (29) is provided, having the edge of its open end provided with inlet opening (6), adjacent to the inner wall of the cap (2), the latter provided with outer conduct (9), said receptacle shaped container (29) having its tubular wall coupled by pressure, or by ultrasound gluing, with vertical wall (31) edges projecting from the inner portion of the outer conduct (9) able to realise, once engaged each other, the receptacle corresponding to the inversion conduct (7).
 13. Device (4) for the controlled delivery of a product (P) according to one of the preceding claims, characterised in that said cap (2), bringing the inner conduct (5), is laterally hinged (20) with the second element with the outer conduct (9) to realise, once engaged each other and closed, said control device (4) and said second element is laterally hinged (17) with a cover (16) provided with snapping closure means (18) engaging the delivery opening (1.0).
 14. Device (4) for the controlled delivery of a product (P) according to one of the preceding claims, characterised in that said outer conduct (9) is realised on the cap (2).
 15. Device (4) for the controlled delivery of a product (P) according to one of the preceding claims, characterised in that said cap (2), engaged with the neck (15) of the container (1), is provided with a bottom re-entrant in said container (1), thus realising an inner receptacle (38) provided with a tubular wall adjacent to the inner tubular wall of the neck (15) of the container (1) and with a bottom surface (39), these latter, provided with inlet conduct (5), being part of the inversion conduct (7) along with the inner bottom wall of the element communicating with the outer conduct (9).
 16. Device (4) for the controlled delivery of a product (P) according to one of the preceding claims, characterised in that the inner end of the outer conduct (9), realising the outlet opening (8), is substantially placed at half height of the receptacle of the inversion conduct (7), to allow to the product (P) level remained within the inversion conduct (7), when the delivery is terminated and the container (1) inverted in the not-delivery position, to have a lower level (14) with respect to said inner end of the outer conduct (9) realising the outlet opening (8), in such a way to make the inner air outflowing through the space obtained by the difference between the two levels, if subjected to a positive variation of volume and pressure.
 17. Device (4) for the controlled delivery of a product (P) according to one of the preceding claims, characterised in that a covering wall (19) is provided, obtained from the bottom wall of the cap (2), and slightly far and raised with respect to the inner end of the outer conduct (9), to allow to avoid that the product (P) remained within the inversion conduct (7), over said outer conduct (9), can outflow in an unchecked way through the delivery opening (10), during the upsetting of the container (1) from the not-delivery position to the delivery position.
 18. Device (4) for the controlled delivery of a product (P) according to one of the preceding claims, characterised in that the lower part of the inversion conduct (7) is provided with an upwardly directed recess, having a concave (21) or sloped (22) wall, to allow to the outer conduct (9) to be extremely short, even if the inner end is substantially at half height of the inversion conduct (7), to allow to limit at the maximum level the product film that can remain within said outer conduct (9) after the delivery step, due to the product capillarity.
 19. Device (4) for the controlled delivery of a product (P) according to one of the preceding claims, characterised in that said outer conduct (9) is substantially angled at 90° and is outside the receptacle of the inversion conduct (7), the latter being provided with an upwardly directed sloped recess (22), and with the outlet opening (8) in the higher position of its tubular wall.
 20. Device (4) for the controlled delivery of a product (P) according to one of the preceding claims, characterised in that opening and closure means of the inner end of the outer conduct (9) are realised by said outer conduct (9) placed on a rotating cap (2), snapping coupled on the container (1) neck (15), rotating within a tubular receptacle (23), said tubular receptacle (23) provided with bottom (24), is engaged with the opposite end (25) on the edge of the neck (15) of the container (1) to realise, along with the bottom of the rotating cap (2), the inversion conduct (7), in such a way that the inner end of the outer conduct (9), corresponding to the outlet opening (8), closed by the bottom wall (27) of a C shaped tubular recess (28), obtained on the tubular receptacle (23), can rotate with respect to said bottom wall (27) to free from the closure the outlet opening (8) and to allow to the product (P) to pass through the outer conduct (9) to-be delivered from the delivering opening (10).
 21. Device (4) for the controlled delivery of a product (P) according to one of the preceding claims, characterised in that said opening and closure means of the inner end of the outer conduct (9) are of the push and pull kind, axial means, realised by a second slidable tubular receptacle (35), having a bottom provided with said outer conduct (9), tubular wall and opposite end opened, telescopically introduced, in a upset, slidable and hermetically sealing position, within the tubular wall of a first inner receptacle (33), obtained from a recess of the cap (2), the latter receptacle (33) being provided with bottom (34), realising, along with the second slidable tubular receptacle (35), the inversion conduct (7), said bottom (34) of the receptacle (35 being provided with inner conduct (5) and with a covering wall (19), where, in the closure position, the second slidable tubular receptacle (35) bearing the outer conduct (9) is pushed within the first inner receptacle (33) obtained from the recess of the cap (2) in such a way that the inner end of said outer conduct (9) can close on said covering wall (19), while in the delivery position the second slidable tubular receptacle (35) bearing the outer conduct (9) is pulled outward in such a way that the inner end of said outer conduct (9) is slightly far from the covering wall (19), so as to realise the opening outlet (8), to allow to the product (P) to pass through the outer conduct (9) and to be delivered from the delivery opening (10).
 22. Device (4) for the controlled delivery of a product (P) according to one of the preceding claims, characterised in that means are provided for the slidable engagement, and provided with a stop, realised by a projecting annular edge (36), placed on the second slidable tubular receptacle (35), sliding within an annular groove (37), realised on the final end of the inner wall of the first inner receptacle (33) obtained from the recess of the cap (2).
 23. Device (4) for the controlled delivery of a product (P) according to one of the preceding claims, characterised in that said opening and closure means provide a screw roto-translation of the inner end of the outer conduct (9) and are realised by a movable opening and closure body (40), movably threadingly engaged on the cap (2), the latter being snapping coupled on the container (1) neck (15), with the inversion conduct (7) realised by the central part of the bottom of the movable opening and closure body (40), provided with outer conduct (9), and by the first inner receptacle (38) obtained from the recess of the cap (2), having its bottom (39) with the inner conduct (5), said central part of the bottom of the opening and closure movable body (40) having an upwardly directed recess (21), to allow to said outer conduct (9) to be very short, even if the final inner end is placed substantially at half height of the inversion conduct (7), where in the closure position, by roto-translation caused by the screwing of the opening and closure movable body (40) on the cap (2), the inner end of said outer conduct (9) can close on the covering wall (19), obtained from the bottom wall (39) of the first inner receptacle (38) obtained from the recess of the cap (2), while in the delivery position, the inner end of said outer conduct (9) is slightly distanced, by roto-translation of the opening and closure movable body (40), from the covering wall (19), so as to realise the opening outlet (8), and to allow to the product (P) to pass through the outer conduct (9) and to be delivered from the delivery opening (10).
 24. Device (4) for the controlled delivery of a product (P) according to one of the preceding claims, characterised in that said axially slidable hermetic sealing and engagement means are realised by an annular wall (41) projecting from the bottom surface of the opening and closure movable body (40), realising the lower part of the inversion conduct (7), slidably and under pressure engaging with the inner tubular wall of the first receptacle (38) obtained from the recess of the cap (2). 